Pascale Le Goff

Stress-induced retrotranslocation of clusterin/ApoJ into the cytosol

Clusterin is a usually secreted glycoprotein with chaperone properties. Recently, it has been suggested that clusterin isoforms reside in the nuclear and cytosolic compartments of human cell types, where they can influence various cellular programs including DNA repair, transcription and apoptosis. Several mechanisms have been proposed to explain this atypical location, including alternative transcription initiation and alternative splicing. However, none of these have been unequivocally established as occurring in live cells. Here we provide direct experimental evidence that in live intact cells, under certain stress conditions, clusterin can evade the secretion pathway and reach the cytosol. This was demonstrated using several complementary approaches. Flow cytometry and selective permeabilization of U251 cell membranes with digitonin allowed detection of cytosolic clusterin in stressed U251 cells. In addition, a stringent enzymatic assay reliant upon the exclusively cytosolic deubiquitinase enzymes confirmed that clusterin synthesized with its hydrophobic secretion signal sequence can reach the cytosol of U251 cells. The retrotranslocation of clusterin is likely to occur through a mechanism similar to the endoplasmic reticulum (ER)‐associated protein degradation pathway and involves passage through the Golgi apparatus. We also report that the ER‐associated ubiquitin ligase Hrd1/synoviolin can interact with, and ubiquitinate clusterin. The possible biological functions of these novel behaviours of clusterin are discussed.

Localization of the estradiol receptor mRNA in the forebrain of the rainbow trout.

In situ hybridization was used to localize the cells that express the estradiol receptor gene (ER) in the forebrain (hypothalamus, preoptic area, telencephalon) of the rainbow trout (Oncorhynchus mykiss). Both sense and anti-sense [35S]UTP-labeled single-stranded RNA probes were generated from the estradiol binding domain of the ER cDNA. The sense probe was used to evaluate the background of the hybridization reaction. In the forebrain, specific signal appeared in three areas: the posterior hypothalamus, the preoptic area, and the ventral telencephalon. Our localization correlates with [3H]estradiol binding studies in other teleost species. In the pituitary, we observed a weak signal when compared to the signal observed in the forebrain (about ten grains/cell in the pituitary against 35 grains/cell in the posterior hypothalamus). A significant difference was also observed between the intensity of labeling per cell when different forebrain nuclei were compared. We provide here evidence for a tissue-specific regulation of the ER mRNA levels in the trout hypothalamo-pituitary axis.

Trout oestrogen receptor sensitivity to xenobiotics as tested by different bioassays

A recombinant yeast system highly and stably expressing rainbow trout oestrogen receptor (rtER) was used in parallel with a more elaborated biological system, trout hepatocyte aggregate cultures to examine the oestrogenic potency of several chemicals commonly found in the environment. In hepatocyte cultures, the vitellogenin gene, whose expression is principally dependent upon oestradiol, was used as a biomarker. Moreover, competitive binding assays were performed to determine direct interaction between rtER and xenobiotics. This paper describes high specificity of our systems for screening potentially oestrogenic chemicals and determining the mode of action of trout ER with oestrogenic compounds. This work also demonstrates that it is important to combine bioassays with in vitro approaches to elucidate the mechanism of xenooestrogen actions.

Unraveling Complex Interplay between Heat Shock Factor 1 and 2 Splicing Isoforms

Chaperone synthesis in response to proteotoxic stress is dependent on a family of transcription factors named heat shock factors (HSFs). The two main factors in this family, HSF1 and HSF2, are co-expressed in numerous tissues where they can interact and form heterotrimers in response to proteasome inhibition. HSF1 and HSF2 exhibit two alternative splicing isoforms, called α and β, which contribute to additional complexity in HSF transcriptional regulation, but remain poorly examined in the literature. In this work, we studied the transcriptional activity of HSF1 and HSF2 splicing isoforms transfected into immortalized Mouse Embryonic Fibroblasts (iMEFs) deleted for both Hsf1 and Hsf2, under normal conditions and after proteasome inhibition. We found that HSF1α is significantly more active than the β isoform after exposure to the proteasome inhibitor MG132. Furthermore, we clearly established that, while HSF2 had no transcriptional activity by itself, short β isoform of HSF2 exerts a negative role on HSF1β-dependent transactivation. To further assess the impact of HSF2β inhibition on HSF1 activity, we developed a mathematical modelling approach which revealed that the balance between each HSF isoform in the cell regulated the strength of the transcriptional response. Moreover, we found that cellular stress such as proteasome inhibition could regulate the splicing of Hsf2 mRNA. All together, our results suggest that relative amounts of each HSF1 and HSF2 isoforms quantitatively determine the cellular level of the proteotoxic stress response.

Drawing a Waddington landscape to capture dynamic epigenetics

Epigenetics is most often reduced to chromatin marking in the current literature, whereas this notion was initially defined in a more general context. This restricted view ignores that epigenetic memories are in fact more robustly ensured in living systems by steady‐state mechanisms with permanent molecule renewal. This misconception is likely to result from misleading intuitions and insufficient dialogues between traditional and quantitative biologists. To demystify dynamic epigenetics, its most famous image, a Waddington landscape and its attractors, are explicitly drawn. The simple example provided, is sufficient to highlight the main requirements and characteristics of dynamic gene networks, underlying cellular differentiation, de‐differentiation and trans‐differentiation.

Caractérisation d'une hémopexine sérique de truite par utilisation d'une protéine recombinante

Abstract Rainbow trout hemopexin was produced by Sf9 cells through the Baculovirus system; the protein is released into the culture medium. It has been purified through two successive chromatographic steps: ion exchange (MonoQ) and chelation (Zn+ affinity). Treatment of the protein by N-glycosidase F reduced its relative mass by 3 000, demonstrating N-glycosylation. Spectrophotometric analysis in the Soret band of protein + hemin mixture revealed characteristics of a hemoprotein (oxidized: λ = 413 nm, dithionite-reduced: λ = 422 nm); the titration curve suggested a 1:1 molar ratio. An anti tHx antiserum was produced; it detected an intense band in the trout serum, but also in the serum of two perciforms: gilt-head sea bream and sea bass; it did not cross-react with the serum of the phylogenetically distant eel.

A model of dynamic stability of H3K9me3 heterochromatin to explain the resistance to reprogramming of differentiated cells

Despite their dynamic nature, certain chromatin marks must be maintained over the long term. This is particulary true for histone 3 lysine 9 (H3K9) trimethylation, that is involved in the maintenance of healthy differentiated cellular states by preventing inappropriate gene expression, and has been recently identified as the most efficient barrier to cellular reprogramming in nuclear transfer experiments. We propose that the capacity of the enzymes SUV39H1/2 to rebind to a minor fraction of their products, either directly or via HP1α/β, contributes to the solidity of this mark through (i) a positive feedback involved in its establishment by the mutual enforcement of H3K9me3 and SUV39H1/2 and then (ii) a negative feedback sufficient to strongly stabilize H3K9me3 heterochromatin in post-mitotic cells by generating local enzyme concentrations capable of counteracting transient bursts of demethylation. This model does not require direct molecular interactions with adjacent nucleosomes and is favoured by a series of additional mechanisms including (i) the protection of chromatin-bound SUV39H1/2 from the turnovers of soluble proteins, which can explain the uncoupling between the cellular contents in SUV39H1 mRNA and protein; (ii) the cooperative dependence on the local density of the H3K9me3 of HP1α/β-dependent heterochomatin condensation and, dispensably (iii) restricted enzyme exchanges with chromocenters confining the reactive bursts of SUV39H1/2 in heterochromatin. This mechanism illustrates how seemingly static epigenetic states can be firmly maintained by dynamic and reversible modifications.

Envisioning metastasis as a transdifferentiation phenomenon clarifies discordant results on cancer

Cancer is generally conceived as a dedifferentiation process in which quiescent post-mitotic differentiated cells acquire stem-like properties and the capacity to proliferate. This view holds for the initial stages of carcinogenesis but is more questionable for advanced stages when the cells can transdifferentiate into the contractile phenotype associated to migration and metastasis. Singularly from this perspective, the hallmark of the most aggressive cancers would correspond to a genuine differentiation status, even if it is different from the original one. This seeming paradox could help reconciling discrepancies in the literature about the pro- or anti-tumoral functions of candidate molecules involved in cancer and whose actual effects depend on the tumoral grade. These ambiguities which are likely to concern a myriad of molecules and pathways, are illustrated here with the selected examples of chromatin epigenetics and myocardin-related transcription factors, using the human MCF10A and MCF7 breast cancer cells. Self-renewing stem like cells are characterized by a loose chromatin with low levels of the H3K9 trimetylation, but high levels of this mark can also appear in cancer cells acquiring a contractile-type differentiation state associated to metastasis. Similarly, the myocardin-related transcription factor MRTF-A is involved in metastasis and epithelial-mesenchymal transition, whereas this factor is naturally enriched in the quiescent cells which are precisely the most resistant to cancer: cardiomyocytes. These seeming paradoxes reflect the bistable epigenetic landscape of cancer in which dedifferentiated self-renewing and differentiated migrating states are incompatible at the single cell level, though coexisting at the population level.